The present invention relates to a feed structure for an antenna. Embodiments of the invention find particular application in flexible feed structures for radio antennas, such as those which can be incorporated into clothing.
Wearable antennas have been developed for use in variety of communications applications. The construction of an antenna using flexible materials has been investigated and can give a relatively discreet result which does not hinder the wearer's movements.
There are several challenges in developing a wearable antenna which can for example be incorporated into clothing. One of these is the feed for delivering communications signals to/from the antenna, these normally being at radio frequencies. The feed itself needs to deliver sufficient power while being relatively undetectable and also robust, for instance to withstand normal movement and handling of the clothing, and washing.
A dipole antenna is a form of antenna known for use in a wearable construction but, in practice, it requires a balanced feed in order to prevent the feed itself from radiating as well as the antenna. If the feed radiates, it reduces the efficiency of the antenna, can distort the radiation/reception pattern and can interfere with other equipment. The output of a radio for use with a wearable communications antenna is unbalanced. It is known to use a transmission line plus a balun to convert the radio output to a balanced antenna feed.
Other constraints with regard to an antenna feed suitable for wearable antennas are that it should be compatible with broadband operation and deliver an adequate signal power for use in the field, for example 5 Watts or more.
According to a first aspect of the present invention, there is provided an antenna feed structure for use with a wearable antenna, the feed structure comprising a microstrip line having a line conductor and a ground plane for mounting on opposite sides of a flexible material, the ground plane having a series of apertures therein, at least partially facing the line conductor when mounted.
Such a microstrip line might be connected to a balun to provide a balanced feed to a planar antenna.
Typical, wearable cloth substrates, such as cotton, are often no more than 1 mm thick and can be no more than 0.5 mm or 0.3 mm. It has been found that, in a microstrip line of conventional design, having a line conductor and a continuous ground plane on opposite sides of a typical, wearable cloth substrate, the conductor has to be very narrow in order to achieve an impedance suitable for use with a communications radio. For example, if the radio has a 50 ohm input/output impedance and the cloth substrate is 0.3 mm thick, the width of the line conductor has to be of the order of 0.8 mm in order to match that impedance. Such narrow conductors are very difficult to realise and fragile in use.
Embodiments of the invention allow a significantly wider conductor to be used to achieve the same impedance by reducing the capacitance of the microstrip line per unit length. A simple means of doing this is to remove sections of the ground plane below the line conductor, thereby reducing the amount of material in the ground plane per unit length.
In use, the line conductor will be affected by the proximity of the ground plane to the body, and will also lose a fraction of the power by induced currents in the body. However, these effects can be kept relatively small as long as the spacing of the removed sections is kept small relative to the signal carrier wavelength. For example, it would be preferable to have five or more, or even ten or more, removed sections per carrier wavelength in the material. This effectively presents a reduced averaged capacitance in the transmission line and avoids problems with matching the line to an antenna.
In embodiments of the invention, although not essential, the apertures in the ground plane might be periodic. For example, they might be provided by circular or rectangular openings providing a ladder-like structure. These openings are preferably at least as wide as the line conductor so as to have maximum effect in reducing the amount of ground plane per unit length. An important factor will therefore be the “duty ratio” of the periodic structure in the ground plane.
According to a second aspect of the present invention, there is provided a wearable antenna assembly comprising a dipole antenna and an antenna feed structure, the assembly being carried at least partially on opposite sides of wearable fabric, and the antenna and feed structure having ground planes constructed from a shared, continuous piece of material. The wearable antenna assembly may comprise an antenna feed structure according to an embodiment of the invention in its first aspect, the feed structure being supported on opposite sides of flexible material having a thickness of not more than 1 mm.
It has been found possible to construct an embodiment of the invention on materials no thicker than 0.5 mm and even on cotton having a thickness of only 0.3 mm. A conventional transmission line feed for an antenna would normally present considerable problems at these separations between the ground plane and the line conductor, particularly in terms of fragility, to achieve appropriate impedance. The perforated ground plane allows a wider line conductor to be used to achieve impedance in a convenient range, preferably around 50 ohms but optionally in the range from 35 ohms to 65 ohms, and this in turn means lower resistance and therefore lower loss.
Rather than printing or otherwise providing the components of the transmission line directly onto a wearable material, it may be preferred to construct the components separately and then attach them to the wearable material. For example, the transmission line components might be constructed out of a metallised carrier such as a metallised fabric. A practical option is laser-cut, metallised nylon which offers quite high precision without adding thickness or stiffness to the wearable material.
Embodiments of the invention allow a suitable antenna feed structure to be provided to communicate signals in a preferred frequency range of approximately 50-500 MHz in spite of the tight requirements of wearable antennas in terms of detectability, robustness and electrical parameters.
An antenna feed structure will now be described as an embodiment of the invention, by way of example only, with reference to the following figures in which:
Referring to
A suitable balun is further discussed below with reference to
The antenna 100 is of known type, being a bow-tie dipole.
The ground plane of the transmission line feed 110 is perforated and provides part of a 50 ohm microstrip line which is further described below with particular reference to
Referring to
The transmission line feed 215 of
The nature of the wearable fabric 205 is not particularly critical. Embodiments of the transmission line feed 215 could be functional on at least most common clothing fabrics. The thickness “h” of the fabric 205 is not critical in the functioning of the transmission line feed 215 but an advantage of embodiments of the transmission line feed 215 is that they remain robust even when designed for fabrics 205 of no more than 1 mm thickness. Indeed, they remain robust for use on clothes such as tee-shirts where the fabric 205 would commonly be no more than 0.5 mm.
The material of the transmission line feed 215 may be of any suitable conductive material and for experimental purposes might be for example copper tape. However, a suitable conductive material for use with wearable fabrics is Nora Dell Nickel-Copper-Silver plated nylon plain weave fabric, manufactured by Shieldex Trading Incorporated, with a quoted average resistivity of 0.005 Ω/sq. The antenna 100 and the ground plane 105, 110 of the balun and the transmission line feed 215 can be laser cut from this material.
Although other attachment techniques might be desirable in practice, a working embodiment of the invention can be constructed using adhesive TESA® tape (manufactured by TESA SE) applied to one side of the laser cut Nora Dell material. The backing is removed from the TESA tape and the design can be pressed on to the wearable fabric 205.
Referring to
Wider tracks are possible however if the effective capacitance per unit length can be reduced. In embodiments of the invention, sections of the ground plane 110 below the conducting line 200 are removed to form openings 300. A transmission line 215 of this kind will be affected by the proximity of the ground plane 110 to the body in use, and will also lose a little power due to induced currents in the body. However, these effects can be kept relatively small if the period of the openings 300 is much smaller than the carrier wavelength in the wearable fabric 205, for instance by a factor of five or even ten or more.
Using this method, the width of the conductor can be kept in a range which is practical to use and for which the line will remain relatively undamaged due to flexing of the wearable fabric. In this way, lines with impedances of ˜50 ohms and below may be realised with conductor widths typically in the range 2-10 mm.
Referring to
Referring to
The return loss of the terminated line 215 shown in
The capacitance introduced by the presence of the body was relatively small. The variation of the return loss, from −20 dB to −15 dB with frequency, indicated that the line impedance is within ˜40% that of the termination in the band 250-500 MHz, that is of the order of 35 Ω. It appeared to be closer to 50 Ω at lower frequencies.
This realisation of the feed line 215 with a punctured ground plane 110 is significantly easier to fabricate than one having dimensions as low as 0.8 mm.
As shown in
Referring to
The Marchand balun 600 consists of two parallel line couplers 605A, 605B and 610A, 610B, with one side of each coupler 605A, 610A connected to the ground plane 110 of the incoming transmission line 215. The other two lines 605B, 610B of the couplers are on the opposite side of the wearable fabric 205 (not shown in
The layout and dimensions of the Marchand balun 600 as described above are particularly convenient for direct coupling to a dipole antenna as well as to a transmission line 215 as described above with reference to
Referring to
A prototype balun 600 was constructed using copper tape as the coupled lines 605, 610 placed on both sides of a 0.2 mm polyester substrate. The estimated dielectric constant of polyester film is approximately 3.2, similar to that of cotton fabric substrate 205, so that structures on the film have dimensions similar to those on the textile. The prototype balun 600 was 200 mm long by 25 mm wide, with 5 mm wide tracks. To realise the correct coupling value, the tracks were separated by ˜0.2 mm. The balun 600 was terminated in a 200 ohm resistor and connected to a 50 ohm flexible coaxial cable. The centre conductor of the coaxial cable was soldered to one of the inner lines and the outer was soldered to the point where the outer lines are connected to form a quarter-wave stub.
The measured return loss of this balun 600 is shown in
A bowtie antenna 100 fed with a Marchand balun 600 as described above was modelled. With the antenna 100 in vacuum, the real part of the complex impedance at the input to a nominal 50 ohm line oscillated around approximately 50 ohms across the 100-500 MHz band. The return loss indicated reasonable radiation efficiency from 100-500 MHz.
Referring to
Embodiments of the invention are suitable for use at radio frequencies, for example together with Multiband Inter/Intra Team Radios (“MBITRs”).
Number | Date | Country | Kind |
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10275069.2 | Jun 2010 | EP | regional |
1010988.2 | Jun 2010 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2011/000994 | 6/29/2011 | WO | 00 | 12/6/2012 |